Cloud-based server computing system for and method of providing cross-platform remote access to 3D graphics applications

ABSTRACT

A server computing system in a client-server computing environment includes a virtual display driver that marshals and transmits graphics application programming interface (API) functions to a client via a network. The server may receive capability information from the client, allowing the virtual display driver to resolve differences between the APIs supported on the server and the client.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation and claims the priority benefit of U.S. patent application Ser. No. 13/399,764 filed Feb. 17, 2012, which is a continuation-in-part and claims the priority benefit of U.S. patent application Ser. No. 13/341,570 filed Dec. 30, 2011, the entireties of which are incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present disclosure relates generally to a server computing system in a client-server computing environment, and more particularly to a server computing system for and method of providing cross-platform remote access to 3D graphics applications.

2. Description of the Related Art

In a client-server computing system, a computer application or program that is running on one computer (i.e., the server) may be accessible to another computer (i.e., the client) over a network, such as over the Internet. The user interface running on the server is exposed and visible to the client. In this way, the client has remote access to the server and the user of the client device can interact with the application that is running on the server.

The server application may be, for example, an application that processes two-dimensional (2D) and/or three-dimensional (3D) graphics. In this example, a 2D and/or 3D graphics application may be used to render graphical objects on a computer display. Currently, in a client-server computing system, the high-level graphics representation (e.g., Direct3D, OpenGL) is reduced to an image (e.g., a bitmap image) at the server. The image is then transmitted from the server to the client over the network. Once received at the client, the image is rendered on the client display. Creating, compressing, and transmitting these image files may result in high CPU utilization (i.e., computing load) at the server, especially when the application displays objects in motion and when there are a large number of remote users sharing the server. Further, images are often large and, therefore, transmitting images to a large number of remote users consumes a large amount of network bandwidth.

BRIEF DESCRIPTION OF THE DRAWINGS

Various inventive embodiments disclosed herein, both as to its organization and manner of operation, together with further objectives and advantages, may be best understood by reference to the following description, taken in connection with the accompanying drawings as set forth below:

FIG. 1 illustrates a block diagram of a client-server computing system for providing cross-platform remote access to 3D graphics applications, according to the present disclosure;

FIG. 2 illustrates a flow diagram of a conventional method of providing cross-platform remote access to 3D graphics applications in a client-server computing system;

FIG. 3 illustrates a flow diagram of a method of providing cross-platform remote access to 3D graphics applications in a client-server computing system, according to the present disclosure; and

FIG. 4 illustrates a flow diagram of a method of providing cross-platform remote access to 3D graphics applications in a client-server computing system, according to a minimum configuration of the present disclosure.

DETAILED DESCRIPTION

The disclosure provides a server computing system in a client-server computing environment that provides cross-platform remote access to 3D graphics applications and methods of efficiently providing graphic commands to a computer (client) located remotely from the server. The server computing system of the disclosure exhibits numerous advantages over existing systems. In various embodiments, the server provides 3D graphics application capabilities to a large number of clients while avoiding excessive computing load. Further, the server computing system of the disclosure may provide such 3D graphics application capabilities at lower network bandwidth requirements. Further still, the server computing system of the disclosure may be configured to service clients operating on different platforms.

FIG. 1 illustrates a block diagram of a client-server computing system 100 for providing cross-platform remote access to 3D graphics applications. Client-server computing system 100 includes a server 110 that is operatively connected to a client 120 and a display 130 via a network 140. Network 140 may be, for example, a local area network (LAN) and/or a wide area network (WAN) for connecting to the Internet. Entities of client-server computing system 100 may connect to network 140 by any wired and/or wireless means.

While client 120 and display 130 are illustrated as separate physical components (e.g., illustrative of a common implementation of a desktop or a workstation computing system, such as clients running natively on Windows, Linux, UNIX, and Mac OS X operating system), the capabilities of such separate components can also be integrated in a single device (e.g., a mobile device or a tablet computer). For example, the mobile device can be an iPad tablet computer on the iOS operating system (Apple Inc., Cupertino, Calif.), or other mobile client on either the Android operating system (Google Inc., Mountain View, Calif.) or the Windows CE operating system (Microsoft Corp., Redmond, Wash.). Thus, as used herein, the terms “client” or “client computer” should be understood to include any such implementations.

Server 110 is a server computing system that includes a server application 112, a server 3D library 114, and a virtual display driver 116 that, in accordance with the client-server model of computing, collectively function to enable server 110 to provide various resources or services to client 120, which may be located remotely from the server. In accordance with the present disclosure, these resources or services pertain to computer graphics.

Client 120 includes a client application 122, a client 3D library 124, and a client display driver 126. Collectively, these elements function to enable the client and the client user to consume computer graphics resources or services provided by server 110.

Server application 112 represents an application executing (i.e., “running”) on server 110. The functionality of server application 112 shall be visible to and accessible by client 120 via network 140. For example, server application 112 may be a computer-aided design (CAD) application, such as AutoCAD (Autodesk, Inc., San Rafael, Calif., USA) or Cadence Virtuoso (Cadence Design Systems, San Jose, Calif.); a medical clinical workflow application, such as Symbia.net (Siemens AG, Munich, Germany); an interactive mapping application, such as Google Earth (Google, Inc.); or a 3D game. The functionality of server application 112 shall be visible to and accessible by client 120 via network 140. For example, the functionality of server application 112 may be accessed from client 120 using a process herein known as application publishing, which is currently supported by products such as GraphOn GO-Global, Microsoft Remote Desktop Services, and Citrix XenApp. Such application publishing may be performed in accordance with teachings of commonly-owned U.S. Pat. No. 5,831,609, filed Jun. 6, 1995, entitled “Method and system for dynamic translation between different graphical user interface systems,” which is incorporated by reference as though fully set forth herein.

Client application 122 represents an application installed on and executing on client 120 that emulates a user interface of server application 112. For example, the client application may run in a browser and be implemented in a scripting language, such as JavaScript, a multimedia platform, such as Adobe Flash, or as a browser add-on (e.g., ActiveX control for Internet Explorer). Additionally, client application 122 may run as a standalone application. Client application 122 may receive various input commands from the user via an input device (not shown in FIG. 1), then transmit these commands to server 110, and update the user interface of client application 122 in response to computer graphics commands transmitted from server 110 back to client 120 over network 140.

Server 3D library 114 and client 3D library 124 provide a set of common interfaces or graphics functions to server 110 and client 120, respectively. These components are also referred to herein as a high-level graphics language or a graphics application programming interface (API). In one embodiment of the disclosure, both server 110 and client 120 utilize a library, such as OpenGL (Khronos Group, Beaverton, Oreg.). This enables server 110 and client 120 to communicate at an interface or a graphics functions level, even if server 110 operates on a different computing platform from client 120. This is in contrast to conventional client-server computing systems that have utilized operating system-specific APIs to accomplish computer graphics rendering, which should not be considered cross-platform.

Virtual display driver 116 is a software code module that enables commands or functions that are called in server 3D library 114 to be marshaled (i.e., encoded) and transmitted to client 120 over network 140. Marshaling (or marshalling) is the process of transforming the memory representation of such commands to a data format suitable for transmission via network 140. For example, virtual display driver 116 assigns an ID to each graphics function and converts function arguments from a platform-specific byte order into a common byte order that all clients can read, regardless of the native byte order of the client device. This encoding allows graphic objects and their motions to be represented much more efficiently than the conventional method of generating an image for each arrangement or view of the objects. Significantly less data must be compressed and transmitted by the server, greatly reducing CPU usage on the server and network bandwidth usage.

Client display driver 126 includes a software code module that receives marshaled data from server 110 via client application 122 and executes the 3D library functions using client 3D library 124. This enables client 120 to handle intensive graphics rendering operations, such as blending or shading, while enabling server 110 to share server application 112 with a large pool of clients. This also reduces the bandwidth requirements of network 140 as pixel array image data (e.g., in the form of Bitmap image files) no longer needs to be transmitted from server 110 to individual clients, such as client 120, as was the case in conventional client-server computing systems.

By way of useful background, FIG. 2 illustrates a flow diagram of a conventional method 200 of providing cross-platform remote access to 3D graphics applications in a client-server computing system. Prior to invocation of the conventional method 200, a server has accepted a connection from a client and a request to a client application on the server. The conventional method 200 may include the following steps.

At a step 210, the server application calls or invokes the appropriate function or functions (i.e., “graphics commands”) in the server 3D library that will satisfy the client request. For example, the graphics commands may include blending or shading.

At a step 212, the server 3D library executes each of the graphics commands and calls a virtual display driver on the server with the resulting pixel image array data (e.g., bitmap image data). As previously described herein, this conventional implementation burdens the server with both intensive graphics rendering operations and with servicing clients, which may be undesirable in architectures where it is desirable that the server support a number of remote users simultaneously.

At a step 214, the virtual display driver on the server encodes the pixel image array data and transmits the information to the client via the network. This step may include conventional data compression techniques, such as zlib encoding.

FIG. 3 illustrates a flow diagram of a method 300 of providing cross-platform remote access to 3D graphics applications using client-server computing system 100 of the disclosure. Method 300 may include, but is not limited to, the following steps.

At a step 310, a server component accepts a connection from client 120. For example, the connection may be established in accordance with a Transmission Control Protocol/Internet Protocol (TCP/IP) model as is known to one of skill.

At an optional step 312, server 110 exchanges capability information (i.e., negotiate protocols) with client 120, which may be of use in later steps of method 300 in which virtual display driver 116 encodes commands from server 3D library 114. For example, the capability information received by server 110 may include information about the particular APIs (e.g., OpenGL windowing APIs) supported by components of client 120, such as client display driver 126. The capability information may include the version or versions of client 3D library 124 (e.g., OpenGL 3.2) that are available on client 120. The capability information may also include any extensions available on client 120 that can act as an adapter between the functionality of different versions of server 3D library 114 and client 3D library 124.

At an optional step 314, server 110 may forward the capability information from the server component that is in direct network communication with client 120 to virtual display driver 116. Virtual display driver 116 then stores the information in a memory so that the information can be quickly accessed. This enables virtual display driver 116 to maintain (e.g., expand, update) a central repository of capability information of all client devices. It also enables virtual display driver 116 to quickly lookup the capability of a particular client 120 at resource or service request time.

At a step 316, server application 112 on server 110 is initialized. In the example of server application 112 being an AutoCAD application, this step may include, for example, server 110 carrying out various startup instructions of the AutoCAD application. Generally, server application 112 loads and initializes server 3D library 114. Then, (or at an earlier or later time) server 3D library 114 queries virtual display driver 116 to determine its capabilities. Virtual display driver 116 generally returns the capabilities of client 120, but may also return capabilities that are not supported by client 120 if virtual display driver 116 or other software on server 110 can convert a command that client 120 does not support into one or more commands that client 120 does support.

At a step 318, server application 112 calls or invokes the appropriate function or functions (i.e., “graphics commands”) in server 3D library 114 in response to a request of client 120. For example, if client 120 issues a request to draw a 3D cube, a call is made to server 3D library 114 to satisfy the “draw 3D cube” request.

At a step 320, server 3D library 114 receives the call made by server application 112 at step 318. Server 3D library 114 then executes the function by making one or more calls to the virtual display driver 116, taking into consideration the version-specific capabilities that were received and stored at step 312. Unlike conventional client-server computing systems, server 3D library 114 does not generally execute the graphics commands and produce a bitmap image.

At a step 322, virtual display driver 116 encodes each of the received graphics calls and transmits the information to client 120 via network 140. According to one aspect of the disclosure, virtual display driver 116 may distinguish between platform-specific graphics calls (i.e., the call is specific to the platform of server 110, e.g., windowing functions) and cross-platform graphics calls. If a platform-specific call is intercepted, virtual display driver 116 can either translate the call to a cross-platform supported interface or to a different, platform-specific call that is supported by client 120. By way of one example, translation may include converting a Microsoft Windows operating system implementation of the OpenGL specification (e.g., a WGL function) to an X11 operating system implementation equivalent (e.g., a GLX function). The capability information of optional steps 312 and 314 may be used to determine the specific translation required for server and client. If a cross-platform graphic call is intercepted, virtual display driver 116 may transmit the call as-is. Alternatively, if the 3D command makes use of only two dimensions and can be transmitted more efficiently via an equivalent 2D command, the 3D command may be converted to the 2D alternative. In all of these cases, the transmitted information is a representation of a graphics command that each client 120 supports.

FIG. 4 illustrates a flow diagram of a method 400 of providing cross-platform remote access to 3D graphics applications in a client-server computing system, according to a minimum configuration of the present disclosure. Method 400 may include, but is not limited to, the following steps.

At a step 410, server 110 receives a request to publish a server application 112 to client 120 via network 140. For example, a request to draw a 3D cube can be received by server 110. Optionally, the request can include information about relevant capabilities of client 120, such as the version or versions of client 3D library 124 supported on client 120.

At a step 412, server application 112 calls or invokes the appropriate function or functions (i.e., “graphics commands”) in server 3D library 114 in response to the request received by server 110. For example, if the request is to draw a 3D cube, the graphics commands may relate to geometric operations and/or rendering options, such as blending or shading.

At a step 414, server 3D library 114 receives the call made by server application 112 and executes the function by making one or more calls to virtual display driver 116. In one embodiment of the disclosure, the calls made to virtual display driver 116 take into consideration the capabilities of client 120 received at step 410. Virtual display driver 116 encodes each of the graphics calls and provides a transmission including the one or more graphics calls to client 120 via network 140.

Various embodiments of the present disclosure allow for the functionality of this disclosure to be performed by an intermediary device, such as a cloud server (not shown), which may be associated with the server 110 and client 120, or reside elsewhere in the network (e.g., in the cloud). For example, while client 120 is interacting with server 110, some of the methods described herein may be offloaded to the cloud server to be performed. Additionally, the cloud server may be used to facilitate interaction between individual or multiple clients and server 110 by performing protocol and/or graphics conversions as described herein. 

What is claimed:
 1. A client computing system for receiving cross-platform remote access to 3D graphics applications, the client computing system comprising: memory that stores a client graphics library that is different from a graphics library hosted at a remote server; a communication interface that: transmits capability information regarding graphics capabilities of the client to the remote server, the graphics capabilities comprising information regarding the client library, transmits a request to the remote server, wherein the server invokes a function responsive to the received request, and receives an encoded graphics call from the remote server, wherein the received graphics call is encoded in accordance with the graphics capabilities of the client regarding the client library; and a processor that executes the encoded graphics call by reference to the client library, wherein the encoded graphics call is executable to perform the invoked function.
 2. The system of claim 1, wherein the server and the client operate on different computing platforms.
 3. The system of claim 1, wherein the communication interface further receives capability information sent over the network from the remote server, the received capability information including information regarding the server graphics library.
 4. The system of claim 3, wherein memory further stores the capability information of the remote server.
 5. The system of claim 1, wherein the capability information further comprises APIs supported by the client.
 6. The system of claim 1, wherein the capability information further comprises one or more extensions available on the client, wherein each extension acts as an adapter between different versions of the server library and the client library.
 7. The system of claim 1, wherein the capability information indicates a version of the client library that is available on the client.
 8. A method for receiving cloud-based cross-platform remote access to 3D graphics applications, the method comprising: storing a client graphics library in memory, wherein the client graphics library is different from a graphics library hosted at a remote server; transmitting capability information regarding graphics capabilities of the client over a network to the remote server, the graphics capabilities comprising information regarding the client library; transmitting a request over the network to the remote server, wherein the server invokes a function responsive to the received request; receiving an encoded graphics call sent over the network from the remote server, wherein the received graphics call is encoded in accordance with the graphics capabilities of the client regarding the client library; and executing the encoded graphics call by reference to the client library, wherein the encoded graphics call is executable by a processor to perform the invoked function.
 9. The method of claim 8, wherein the server and the client operate on different computing platforms.
 10. The method of claim 8, further comprising receiving capability information sent over the network from the remote server, the received capability information including information regarding the server graphics library.
 11. The method of claim 10, further comprising storing the capability information of the remote server in memory.
 12. The method of claim 8, wherein the capability information further comprises APIs supported by the client.
 13. The system of claim 8, wherein the capability information further comprises one or more extensions available on the client, wherein each extension acts as an adapter between different versions of the server library and the client library.
 14. The system of claim 8, wherein the capability information indicates a version of the client library that is available on the client.
 15. A non-transitory computer-readable storage medium, having embodied thereon a program executable by a processor to perform a method for providing cross-platform remote access to 3D graphics applications, the method comprising: storing a client graphics library that is different from a graphics library hosted at a remote server; transmitting capability information regarding graphics capabilities of the client to the remote server, the graphics capabilities comprising information regarding the client library; transmitting a request to the remote server, wherein the server invokes a function responsive to the received request; receiving an encoded graphics call from the remote server, wherein the received graphics call is encoded in accordance with the graphics capabilities of the client regarding the client library; and executing the encoded graphics call by reference to the client library, wherein the encoded graphics call is executable to perform the invoked function. 